Project description:Response of Alexandrium tamarense towards live copepods and respective waterborne cues

Project description:Two Alexandrium fundyense (former tamarense) genotypes with different lytic capacties were analyzed with respect to their response towards co-occuring protistan grazers (Polykrikos) grazing on conspecifics. One Alexandrium genotype was able to lyse the grazer whereas the other genotype completely lacks this ability. The difference in their genotypes resulted in the creation of different niches and in difference in their gene expression response.

Project description:Effect of different pCO2 levels on Alexandrium tamarense

Project description:Collected from the toxic dinoflagellate Alexandrium ostenfeldii

Project description:Alexandrium tamarense Transcriptome

Project description:Recognition and rejection of chemically defended prey is critical to maximizing fitness for predators. Paralytic shellfish toxins (PSTs) which strongly inhibit voltage-gated sodium channels in diverse animal taxa are produced by several species of the bloom-forming algal genus Alexandrium where they appear to function as chemical defenses against grazing copepods. Despite PSTs being produced and localized within phytoplankton cells, some copepods distinguish toxic from non-toxic prey, selectively ingesting less toxic cells, in ways that suggest cell surface recognition perhaps associated with non-polar metabolites. In this study LC/MS and NMR-based metabolomics revealed that the non-polar metabolomes of two toxic species (Alexandrium catenella and Alexandrium pacificum) vary considerably from their non-toxic congener Alexandrium tamarense despite all three being very closely related. Toxic and non-toxic Alexandrium spp. were distinguished from each other by metabolites belonging to seven lipid classes. Of these, 17 specific metabolites were significantly more abundant in both toxic A. catenella and A. pacificum compared to non-toxic A. tamarense suggesting that just a small portion of the observed metabolic variability is associated with toxicity. Future experiments aimed at deciphering chemoreception mechanisms of copepod perception of Alexandrium toxicity should consider these metabolites, and the broader lipid classes phosphatidylcholines and sterols, as potential candidate cues.

Project description:Biodiversity of Phycosphere Microbiota from Toxic Marine Dinoflagellates, Alexandrium tamarense Metagenome

Project description:Alexandrium tamarense EST project

Project description:Alexandrium tamarense Group 3 Transcriptome

Project description:Alexandrium tamarense Raw sequence reads